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| Total Pages | : 17 |
| Release | : 2003 |
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| Author | : Muneeb Dogar |
| Publisher | : |
| Total Pages | : |
| Release | : 2013 |
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"The leading-edge vortical flow structure over a 65 slender (DW65) and a 50 non-slender (DW50) delta wing was investigated at Reynolds number of order 105. Particular emphasis was placed in the variation of vortex flow quantities and critical flow parameters with change in angle of attack and chordwise distance. In addition, the progression of vortex breakdown with angle of attack was documented based on pressure and three-dimensional velocity information. A glimpse of wake-vortex evolution was also discussed. Moreover, aerodynamic lift and drag forces were evaluated based on wake survey analyses and compared with direct force balance measurements. Special attention was focused on drag characterization based on lift dependency where Maskell formulation was adopted for the estimation of induced drag. The results showed that the flow over DW65 and DW50 has some qualitative resemblances but quantitatively they are two contrasting flows. Prior to the breakdown, in the case of DW65, the vortical flow is near-axisymmetric but in the case of DW50, the vortex and axial core never matches and even the definition of distinctive vortex center is often ambiguous except at higher angles of attack, moreover the axial core was always accompanied by large momentum deficit. The variation of vortex flow quantities in streamwise direction showed self-similar behavior when plotted against radial distance scaled by local semi-span while interestingly for DW50 self-similar behavior was showed only by the variation of total pressure loss about the pressure core. It was established that the flow over DW50 was marred by an active interaction of vortical and boundary layer flow due to the close proximity of vortex to the wing surface. For the first time the progression of vortex breakdown over the wing surface was reported on the basis of three-dimensional flow information which elucidated the respective indicators of breakdown for slender and non-slender delta wings. Lastly, wake survey analyses were carried and comparison of different lift computational models and direct measurement were presented. Moreover, the estimation of profile drag is sensitive to the definition of wake region whereas vortex breakdown upstream of trailing-edge resulted in underestimation and overestimation of induced drag and CL, respectively. For all the cases of slender wing and high angle of attack cases of non-slender delta wing showed that the induced drag always constituted more than 50% of the total drag. The results provided here provided a deepened and extended insight on vortical and aerodynamics characteristics of slender and non-slender delta wing. " --
| Author | : Lok Sun Ko |
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| Total Pages | : |
| Release | : 2017 |
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"Reverse or inverted delta wing planforms have been employed extensively in the Lippisch-type wing-in-ground effect (WIG) craft for the past few decades. Despite their industrial applicability and popularity, the aerodynamics and the vortex flowfield generated by the reverse delta wing are, however, not available in archived publications. Extensive experimental investigations utilizing particle image velocimetry, force balances, and dye and smoke-wire flow visualizations were, therefore, conducted in this study to better understand the aerodynamic load generation and the vortex flow structure of a reverse delta wing, both slender and non-slender. The results show that for a reverse delta wing in a free stream the wing stall was delayed and had a lowered lift and drag compared to a regular or conventional delta wing at the same angle of attack. The drag reduction of the reverse delta wing, however, underperformed the decrease in the lift, rendering an improved lift-to-drag ratio compared to the regular delta wing. More importantly, the upper surface flow of the reverse delta wing was found to be characterized by the unique multiple spanwise vortex filaments. In contrast to the leading-edge vortex breakdown-induced stalling of the regular delta wing, the stalling mechanism of the reverse delta wing was found to be triggered by the breakdown of the multiple spanwise vortex filaments. Meanwhile, the reverse-delta-wing vortices were also found to be located outboard, suggesting their irrelevance to the lift generation of the reverse delta wing. The lift of the reverse delta wing was found to be mainly generated by the pressure acting on its lower surface, while the upper surface acts like a wake generator. These two streamwise counter-rotating vortices generated by the reverse delta wing were also found to became nearly axisymmetric at 0.7 chord downstream from the leading edge of the reverse delta wing. For a non-slender reverse delta wing (i.e., with a sweep angle less than 55 deg), the above-mentioned findings were found to remain unchanged but had a much smaller magnitude compared to its slender counterpart.Finally, in order to enhance the lift generation capability of the reverse delta wing, passive Gurney flaplike strips, of different heights and configurations, were applied to both the side edges and the leading edges of the reverse delta wing. The addition of the side-edge strips was found to produce a leftward shift of the lift curve, resembling a conventional trailing-edge flap, and a large lift enhancement. The large lift increment overwhelmed the corresponding drag increase, thereby leading to a further improved lift-to-drag ratio compared to the clean reverse delta wing. The lift and drag coefficients were also found to increase with the strip height. The side-edge strip-equipped wing also produced a strengthened vortex compared to its baseline wing counterpart, while the leading-edge strips were found to persistently produce a greatly diffused vortex flow, which therefore suggests a promising wingtip vortex control alternative. The downward leading-edge strip was found to be capable of delivering a delayed stall and an increased maximum lift coefficient compared to the clean baseline wing. In summary, the present first-of-its-kind experimental findings on the reverse delta wing will not only advance our understanding of the lift and drag generation and the vortex flow characteristics, but can also serve as benchmark data for CFD validation. The present study will also lay a foundation for the study of the effects of ground proximity on the reverse delta wing, and, more importantly, lead to an improved design of wing-in-ground effect craft. " --
| Author | : Michael Denis Nelson |
| Publisher | : |
| Total Pages | : 368 |
| Release | : 1991 |
| Genre | : Oscillating wings (Aerodynamics) |
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| Author | : National Aeronautics and Space Adm Nasa |
| Publisher | : |
| Total Pages | : 162 |
| Release | : 2018-11-18 |
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| ISBN | : 9781731351593 |
The vortical flow over a delta wing contributes an important part of the lift - the so called nonlinear lift. Controlling this vortical flow with its favorable influence would enhance aircraft maneuverability at high angle of attack. Several previous studies have shown that control of the vortical flow field is possible through the use of blowing jets. The present experimental research studies vortical flow control by applying a new blowing scheme to the rounded leading edge of a delta wing; this blowing scheme is called Tangential Leading Edge Blowing (TLEB). Vortical flow response both to steady blowing and to unsteady blowing is investigated. It is found that TLEB can redevelop stable, strong vortices even in the post-stall angle of attack regime. Analysis of the steady data shows that the effect of leading edge blowing can be interpreted as an effective change in angle of attack. The examination of the fundamental time scales for vortical flow re-organization after the application of blowing for different initial states of the flow field is studied. Different time scales for flow re-organization are shown to depend upon the effective angle of attack. A faster response time can be achieved at angles of attack beyond stall by a suitable choice of the initial blowing momentum strength. Consequently, TLEB shows the potential of controlling the vortical flow over a wide range of angles of attack; i.e., in both for pre-stall and post-stall conditions. Lee, K. T. and Roberts, Leonard BLOWING; DELTA WINGS; FLOW DISTRIBUTION; LEADING EDGES; VORTICES; AIRCRAFT MANEUVERS; ANGLE OF ATTACK; MOMENTUM; NONLINEARITY; STABILITY...
| Author | : Hans Josef Rath |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 543 |
| Release | : 2007-12-10 |
| Genre | : Technology & Engineering |
| ISBN | : 3540332871 |
This volume collects contributions to the 14th Symposium of the STAB (German Aerospace Aerodynamics Association). The association involves German scientists and engineers from universities, research establishments and industry who are doing research and project work in numerical and experimental fluid mechanics and aerodynamics, mainly for aerospace but for other applications, too. The volume gives a broad overview of ongoing work in Germany in this field.
| Author | : William H. Wentz (Jr.) |
| Publisher | : |
| Total Pages | : 160 |
| Release | : 1966 |
| Genre | : Delta wing airplanes |
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| Author | : Dashnor Hoxha |
| Publisher | : Trans Tech Publications Ltd |
| Total Pages | : 740 |
| Release | : 2013-08-30 |
| Genre | : Technology & Engineering |
| ISBN | : 3038262145 |
Collection of selected, peer reviewed papers from the 2013 4th International Conference on Mechanical and Aerospace Engineering (ICMAE 2013), July 20-21, 2013, Moscow, Russia. The 127 papers are grouped as follows: Chapter 1: Aerodynamics and Aeronautic; Chapter 2: Fluid Dynamics, CFD and other Computational Methods; Chapter 3: Computational Techniques, Simulation and Numerical Analysis; Chapter 4: Dynamics and Vibration; Chapter 5: Motors, Combustion, Propulsion, Fuel and Emission Control; Chapter 6: Instrumentation and Measurement, Control Systems and Automation; Chapter 7: Trajectory Design, Navigation and Control; Chapter 8: Materials Characterization and Technologies; Chapter 9: Design, Industry and Manufacturing Technologies; Chapter 10: Thermal Analysis Technologies, Heat Exchange Engineering and Applications.
| Author | : Chih Shih |
| Publisher | : |
| Total Pages | : 106 |
| Release | : 1986 |
| Genre | : Airplanes |
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| Author | : |
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| Total Pages | : 8 |
| Release | : 1994 |
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The overall objective of this research program was to characterize the unsteady flow structure on wings having swept edges. Wings were subjected to global control, involving motion of the entire wing, and local control, involving perturbations at specified locations on the surface of the wing. New types of experimental facilities and image acquisition and processing techniques have allowed determination of the instantaneous vorticity distributions and streamline patterns of the flow. The occurrence of vortex breakdown and stall and their phase shifts relative to the wing motion and to control at the leading-edges have been interpreted in terms of new flow mechanisms. Delta Wings, Vortex Breakdown, Laser Diagnostics.
